Authors: Marina Kapsali, John S. Anagnostopoulos

Abstract:

On the basis of comparative analysis of alternative “development scenarios” for electricity generation, the main objective of the present study is to investigate the techno-economic viability of high wind energy (WE) use at the local (island) level. An integrated theoretical model is developed based on first principles assuming two main possible scenarios for covering future electrification needs of a medium–sized Greek island, i.e. Lesbos. The first scenario (S1), assumes that the island will keep using oil products as the main source for electricity generation. The second scenario (S2) involves the interconnection of the island with the mainland grid to satisfy part of the electricity demand, while remarkable WE penetration is also achieved. The economic feasibility of the above solutions is investigated in terms of determining their Levelized Cost of Energy (LCOE) for the time-period 2020-2045, including also a sensitivity analysis on the worst/reference/best Cases. According to the results obtained, interconnection of Lesbos Island with the mainland grid (S2) presents considerable economic interest in comparison to autonomous development (S1) with WE having a prominent role to this effect.

Keywords: Electricity generation cost, levelized cost of energy, mainland, wind energy surplus.

Digital Object Identifier (DOI): doi.org/10.5281/zenodo.1123693

Procedia APA BibTeX Chicago EndNote Harvard JSON MLA RIS XML ISO 690 PDF Downloads 1030

References:

[1] J. K. Kaldellis, “Maximum wind energy contribution in autonomous electrical grids based on thermal power stations,” Appl. Therm. Eng., Vol. 27, pp. 1565-1573, 2007.
[2] D. A. Katsaprakakis, D. G. Christakis, E. A. Zervos, D. Papantonis, and S. Voutsinas, “Pumped storage systems introduction in isolated power production systems,” Renew. Energ., Vol. 33, pp. 467-490, 2008.
[3] J. S. Anagnostopoulos, and D. E. Papantonis, “Simulation and size optimization of a pumped–storage power plant for the recovery of wind-farms rejected energy,” Renew. Energ., Vol. 33, 1685-1694, 2008.
[4] Hellenic Transmission System Operator (HTSO), “Study for Aegean islands interconnection with the mainland grid. Phase A”, 2010. Available at: http://www.desmie.gr. (accessed in May 2015).
[5] Regulatory Authority of Energy (RAE), “Update of the strategic study for the interconnection of autonomous island networks to the mainland power system”, 2008. Available at: http://www.rae.gr.
[6] M. Papadopoulos, N. Boulaxis, M. Tsili, and S. Papathanasiou, “Increased wind energy exploitation via interconnection of Aegean islands to the mainland grid,” in Proc. 19th International Conf. on Electricity Distribution, Vienna, 2007.
[7] P. N. Georgiou, G. Mavrotas, and D. Diakoulaki, “The effect of islands’ interconnection to the mainland system on the development of renewable energy sources in the Greek power sector,” Renew. Sust. Energ. Rev., Vol. 15, pp. 2607–2620, 2011.
[8] Hellenic Transmission System Operator (HTSO), “Development of the Electric Power System of Crete-Interconnection to the System of the Mainland”, 2011. Available at: http://www.desmie.gr. (accessed in May 2015).
[9] J. K. Kaldellis, M. Kapsali, and K. A. Kavadias, “Energy balance analysis of wind-based pumped hydro storage systems in remote islands electrical networks,” Appl. Energ., Vol. 87, pp. 2427-2437, 2010.
[10] M. Kapsali, J. S. Anagnostopoulos, and J. K. Kaldellis, “Wind powered pumped-hydro storage systems for remote islands: A complete sensitivity analysis based on economic perspectives,” Appl. Energ., Vol. 99, pp. 430-444, 2012.
[11] Regulatory Authority of Energy (RAE), “Amendment of the 85/2007 decision of RAE concerning the methodology of estimating maximum power absorption margins in the non-interconnected Greek islands”, (in Greek), 2008. Available at: http://www.rae.gr. (accessed in May 2015).
[12] Regulatory Authority of Energy (RAE), “Amendment of the 96/2007 decision of RAE concerning the development of photovoltaic power stations in the islands, the allocation methodology of the available power in the islands and the identification of the “estimated’ allocation measure. Implementation of the new allocation measure to the island of Crete”, (in Greek), 2008. Available at: http://www.rae.gr. (accessed in May 2015).
[13] J. K. Kaldellis, K. A. Kavadias, and D. Zafirakis, “Experimental validation of the optimum photovoltaic panels' tilt angle for remote consumers,” Renew. Energ., Vol. 46, pp. 179-191, 2012.
[14] ROKAS Renewables, “Aegean Link Project”, 2008. Available at: http:// www.pvaigaiou.gov.gr/. (accessed in July 2015).
[15] Regulatory Authority of Energy (RAE), “Calculation of average variable cost of electricity production from conventional units in the autonomous islands, under the provisions of Article 143 of Law. 4001/2011, budgeted figures for the first half of the year 2013”, (in Greek), 2013. Available at: http://www.rae.gr. (accessed in May 2015).
[16] Ministry of Environment, Energy & Climate Change (MEEC), “National Energy Plan: Roadmap to 2050”, 2012. Available at: http://www.ypeka.gr/. (accessed in September 2015).
[17] S. Papathanasiou, E. Karamanou, S. Papaefthimiou, and K. Papastamoulos, “Parametric investigation of energy and capacity tariffs for hybrid power stations in non-interconnected islands”, (funded by Regulatory Authority for Energy (RAE) of Greece), 2010. Available at: http://www.rae.gr. (accessed in September 2015).
[18] International Energy Agency (IEA), “World Energy Outlook”, 2012. Available at: http://www.worldenergyoutlook.org/.(accessed in September 2015).
[19] International Energy Agency (IEA), “Energy technology perspectives 2010 – Scenarios and strategies to 2050”, 2010. Available at: http://www.iea.org/.
[20] Hellenic Electricity Market Operator (LAGIE), “Feed in tariffs for RES applications”, 2015. Available at: http://www.lagie.gr/.
[21] Independent Power Transmission Operator (IPTO), “Cost/benefit study for Cyclades interconnection with the mainland grid”, 2013. Available at: http://www.admie.gr.
[22] T. Drobik, 2006. “High-voltage direct current transmission lines”, IEEE Conference Publishing.
[23] N. B. Negra, J. Todorovic, and T. Ackermann, “Loss evaluation of VAC and HVDC transmission solution for large offshore wind farms,” Electr. Pow. Syst. Res., Vol. 76, pp. 916-927, 2006.
[24] M. Kapsali, and J. K. Kaldellis, “Combining hydro and variable wind power generation by means of pumped-storage under economically viable terms,” Appl. Energ., Vol. 87, pp. 3475-3485, 2010.
[25] S. A. Papathanassiou, and N. G. Boulaxis. “Power limitations and energy yield evaluation for wind farms operating in island systems,” Renew. Energ., Vol. 31, pp. 457-479, 2005.
[26] Regulatory Authority of Energy (RAE), 2013. “Code of management of electric power systems on the non-interconnected islands”, 2013. Available at: http://www.rae.gr. (accessed in October 2015).